DE69113429T2 - HIGH FREQUENCY HEATING DEVICE. - Google Patents

Description

TECHNICAL AREA

The present invention relates to an electronic oven for heating food, liquids, etc., a heat treatment machine for heat treatment of wastes or a high frequency heating device for heating catalysts, etc., which are arranged on mobile devices such as motor vehicles, a ship or the like.

BACKGROUND OF THE INVENTION

From EP-A-0 171 170 a high frequency heating device is known which is arranged on a transport device for people, animals, etc., with a DC voltage source, a voltage converter which receives DC voltage from the DC voltage source, a magnetron which is operated by the output signal of the voltage converter, a DC voltage output detection device for directly or indirectly detecting the level of the output signal of the DC voltage source, and a controller for controlling the operation of the voltage converter.

Conventionally, as a replacement for the high-frequency heating device of the type represented by electronic ovens, a so-called electronic oven for general household use adapted to the use of a mains voltage source is used in combination with an alternator for exclusive use with a predetermined frequency and a predetermined alternating voltage.

Figure 13 is a view showing an arrangement of a known high frequency heating device. In this drawing, the high frequency heating device is used in a tour bus or the like. In Figure 13, an engine 2 for generating transportation power is provided in a vehicle and transportation power is transmitted to tires 3 to transport passengers.

A so-called electronic oven 5 is mounted in such a vehicle to carry out microwave heating of food 4. This electronic oven 5 is formed by a voltage source 9 with a ferroresonant step-up transformer 6, a resonance capacitor 7 and a high-voltage diode 8, a magnetron 10 and an oven 11 and can be used by connecting a mains voltage source to the terminals 12 and 13. In order to cause the electronic oven 5 to exhibit normal functions, it is elementary to supply a predetermined voltage of e.g. 100 V with a predetermined frequency of e.g. 60 Hz to the terminals 12 and 13.

Therefore, conventionally, by using an AC generator 16 provided with an exclusive use of a camber generator 14 and a dynamo 15 driven by the camber generator 14, a microwave heating device having an arrangement as shown is realized for home use by the AC generator 16 and the electronic oven 5 and used in the motor vehicle.

On the other hand, due to the wide variety of motor vehicles in recent years, long-distance transport, long-distance driving or outdoor recreational activities such as sailing, camping, etc. have become popular and therefore a demand for drinking and eating in places without a mains power source, e.g. in a motor vehicle, has increased.

Meanwhile, the need for the use of micro-heating has increased, particularly to improve the effect of catalysts for cleaning exhaust gases from machines such as diesel engines.

Thus, the need for high frequency heating devices to be easily deployed, especially in places without a mains voltage source, has increased.

However, based on the above-described prior art, it is difficult to sufficiently meet the increasing demand of using high frequency heating devices in places without a commercial power source. Namely, in the prior art, a special AC power source is required that ensures the frequency stability and the voltage equivalent to the commercial power source, and therefore a high-precision stabilized AC power source for exclusive use was absolutely necessary. This is because the ferroresonance transformer is used in the power source for driving the magnetron. to stabilize the operation and output signal of the magnetron through its resonance with the resonance capacitor.

Therefore, the prior art high frequency heating device is very large, heavy and expensive due to the need for the stabilized AC power source, the ferroresonant transformer, etc., and is difficult to handle due to poor controllability. In particular, the application of the ferroresonant transformer means the need for the stabilized AC power source for exclusive use, and therefore it is impossible to avoid the above-mentioned inconveniences.

Therefore, it is difficult to create a high frequency heating device at low cost that can be easily used in places where it is difficult to obtain a power source, such as in a mobile room of a motor vehicle, a yacht or the like.

DISCLOSURE OF THE INVENTION

Accordingly, objects of the present invention are to meet the increasing demand for high frequency heating devices in which not only a high voltage can be easily supplied to a magnetron but necessary stable dielectric heating functions can be provided even in places where it is difficult to find a commercial power source even when a DC power source with poor output stability attached to a transportation device for people, objects, animals, etc. is used, and to improve reliability and safety and to realize convenient operability.

Therefore, a DC voltage source, a voltage converter for receiving the DC voltage obtained from the DC voltage source, a magnetron which is actuated by the output signal of the voltage converter, a DC voltage detection device for directly or indirectly detecting the output signal of the DC voltage source and a converter control for controlling the operation of the voltage converter is characterized by an anode current detection device for detecting an anode current flowing through the magnetron, a reference signal generator, and an error amplifier for outputting a difference between an output signal of the anode current detection device and an output signal of the reference signal generator, wherein the controller is a pulse width modulation (PWM) control circuit for controlling the operation of the voltage converter based on an output signal of the spring amplifier so that the output signal of the reference signal generator is controlled in accordance with the output signal of the DC voltage detection device.

Therefore, even if a voltage generator and a dynamo which are poor in output stability and are inexpensive due to their simple construction are used, the required dielectric heating function can be stably achieved.

BRIEF DESCRIPTION OF THE DRAWINGS

Figure 1 is an overall block diagram of an embodiment of the present invention,

Figure 2 is a circuit diagram of the high frequency heating device,

Figures 3(a), 3(b) and 3(c) are working waveform diagrams of a voltage converter of the high frequency heating device,

Figure 4 is a working characteristic of the voltage converter of the high frequency heating device,

Figure 5 is a circuit diagram of a second embodiment of a voltage converter control of the high frequency heating device,

Figure 6 is a characteristic curve of the number of revolutions of a dynamo and the output voltage in the high frequency heating device,

Figure 7 is a characteristic curve of the output voltage of the dynamo and the high frequency output in the high frequency heating device,

Figures 8(a) and 8(b) are characteristics of high frequency heat output and heating period of the high frequency heater,

Figure 9 is an overall block diagram of a third embodiment of the present invention, Figure 10 is a cross-sectional view of a housing of a fourth embodiment of the present invention,

Figure 11 is a cross-sectional view of a housing of a fifth embodiment of the present invention,

Figure 12 is a cross-sectional view of a housing of a sixth embodiment of the present invention, and

Figure 13 is a view showing an arrangement of a high frequency heating device mounted on a motor vehicle.

BEST MODE FOR CARRYING OUT THE INVENTION

Hereinafter, embodiments of the present invention will be described together with the drawings. Figure 1 is a block diagram showing a high frequency heating device of an embodiment of the present invention which is used in a motor vehicle.

In the drawing, the rotational energy of a machine 20 acting as a prime mover is transmitted to the wheels 21 and simultaneously to an AC dynamo 22. An output voltage of the dynamo 22 is supplied to a rectifier 23. A DC output of this rectifier acts as a voltage source for supplying electric voltage to a voltage converter 24. This voltage converter 24 is constituted by a switching circuit 25 having a switching transistor and a resonance capacitor and a step-up transformer 26 also acting as a resonance inductor. A high voltage output of this voltage converter is supplied to a magnetron 28 through a rectifier 27. An electromagnetic output wave of the magnetron is supplied to a food 30 in an oven 29 so that dielectric heating of the food 30 can be carried out.

In order to stably control the rotation speed of the engine 20, it is now necessary to carry out an advanced control of the fuel supply and the combustion state. In the case where the engine 20 also acts as a drive motor in the motor vehicle, as in this embodiment, the number of revolutions of the machine is forced to vary widely in accordance with the necessary rotation of the wheels 21 corresponding to the running speed of the motor vehicle. Therefore, the output of the dynamo 22 varies widely in accordance with the number of revolutions of the prime mover 20.

In order not only to realize excellent dielectric heating of the feed 30 in such a widely changing working state of the power machine 20, but also to prevent deterioration of reliability by applying an overload to the dynamo 22, the working state of the voltage converter 24, that is, the amount of electrical energy conversion, must be controlled in accordance with the possibility of generating electrical energy in one form or another. For this reason, a voltage detecting means (generated electric power output detecting means) 31 for detecting the generated electric power of the dynamo 22 as an output voltage of the rectifying means 23, and a voltage converter controller 32 for controlling the switching circuit 25 of the voltage converter 24 in response to a signal of the voltage detecting means 31 are provided so that the voltage converter 24 is operated in accordance with the level of the generated electric output signal.

With such an arrangement, even in a large range of variation of the speed of the engine 20, the reliability is not impaired by the overload condition and perfect microwave heating of the food 30 is achieved.

Fig. 2 is a circuit diagram showing another detailed structure of the above-mentioned embodiment of the present invention shown in Fig. 1. Numerals identical to those in Fig. 1 denote corresponding elements and the description thereof is abbreviated. An output signal of the dynamo 22 is rectified by the rectification circuit 23 formed by diodes 33, 34 and 35 and the capacitor to be converted into a DC voltage. This DC voltage is supplied to a voltage converter 24 formed by a coil 37, a bypass capacitor 38, a resonance capacitor 39, a step-up transformer 40, a transistor (IGBT) 41, a diode 42, etc. An output signal of the voltage converter 24 is outputted as an output signal from two secondary windings of the step-up transformer 23. 40 is supplied to the magnetron 28. The output of the high-voltage secondary winding is converted into a high DC voltage by the high-voltage rectification circuit 27 formed by a capacitor 43 and diodes 44 and 45 and then supplied to the magnetron 28. On the other hand, the output of the low-voltage secondary winding is directly supplied to a cathode of the magnetron 28.

The converter controller 32 mainly includes a converter control circuit 48 which detects a collector voltage of the IGBT 41 as a synchronous signal through the resistors 46 and 47 to control the on-period Ton of the IGBT 41 in synchronism with the resonance circuit formed by the resonance capacitor 39 and the step-up transformer 40. Figures 3(a), 3(b) and 3(c) are waveform diagrams of a collector voltage Vce, a collector current Icd and a gate voltage Vg of the IGBT 41 and illustrate working states of the above-mentioned converter. The converter control circuit 48 detects a point P of the intersection between Vce and its source voltage Vcc and outputs the gate voltage Vg after a predetermined period Td (referred to as "synchronous oscillation control"). Then, the converter control circuit 48 controls the pulse width Ton of the gate voltage so that a desired electromagnetic wave output of the magnetron 28 is obtained. Reference numeral 49 denotes a voltage source circuit. A terminal voltage of a resistor 50 is fed back to the converter control circuit 48 as an anode current detection signal of the magnetron 28. The period Ton is controlled by this feedback signal so that the electromagnetic wave output of the magnetron 28 can be controlled to an arbitrary setting value.

The magnitude of the output generated electric voltage of the dynamo 22 is detected by the resistors 51 and 52 as a DC output voltage of the rectification circuit 23 and is output to the converter control circuit 48. In response to this detection signal, the converter control circuit 48 is able to control the operating state of the converter 24. Thus, even if the working state of the engine 20 varies widely, deterioration of reliability by generating an overload state of the dynamo 22 does not occur and proper heating with electromagnetic waves can be carried out by the magnetron 28.

Namely, when the number of revolutions of the generator 22 drops excessively, the output of the dynamo also drops. Therefore, the period Ton of the IGBT 41 is reduced so that the output voltage of the dynamo falls within a range that allows stable operation of the voltage converter 24, while the consumed electric power of the voltage converter is controlled to correspond to the level of the output of the dynamo. The relationship between Ton and Po is shown in Figure 4, and Po changes quadratically with Ton. This is because the electric power delivered to the magnetron 28 is substantially proportional to the square of Icd by the operation of the converter shown in Figure 3. In contrast, in the case where the output of the dynamo is too high, Po becomes too high if Ton remains as it is, with the result that the IGBT 41, etc., may be thermally damaged not only by the excessive increase in the heat dissipation but by the excessive increase in the loss of the voltage converter 24. Accordingly, in this case too, Ton is set to a small value so that high reliability and proper heat dissipation are achieved.

Figure 5 is a circuit diagram showing a more detailed arrangement of the present invention from the above-mentioned Figures 1 and 2. In Figure 5, numbers identical to those in Figures 1 and 2 indicate corresponding elements and the detailed description thereof is therefore abbreviated.

In Fig. 5, the converter controller 32 is constituted by a pulse width modulation (PWM) control circuit 53 for controlling tone which has a function of synchronous oscillation control as described in Fig. 3, a differential amplifier 55 for outputting a difference signal between an anode current detection signal of the magnetron 28 and a signal of a reference signal generator 54 to the PWM control circuit 53, and a heater control circuit 56 for controlling a reference signal of the reference signal generator 54 to its corresponding value on the basis of a signal of the output generated electric power detector 31 for detecting the amount of output electric power of the dynamo 22. This heater control circuit 56 can be easily constituted by using, for example, a microcomputer, and is adapted to carry out an overall adjustment of the amount of output of the electromagnetic waves. of the magnetron in accordance with a predetermined program as described below.

When the number N of revolutions of the dynamo 22 changes according to the change in the working state of the engine 20, the detected voltage Vo of the output generated electric power detector 31 changes as shown in Fig. 6, and there is a fixed correlation between N and Vo. Therefore, by detecting Vo instead of N, the arrangement of Fig. 5 in which the signal detection circuit is simplified as much as possible can be used.

Figure 7 shows an example illustrating how the heater control circuit 56 controls the output Po of the magnetron 28 with respect to Vo as the detected output of the dynamo. When Vo decreases by a, b and c, Po is controlled down by A, B and C. In a region where Vo is smaller than c, Po is set to substantially 0 or a state where the converter is operated with such a small electric input voltage that Po becomes substantially 0. Thus, the voltage converter 24 is operated with the extremely small Vo, so that occurrence of defects such as the confirmation of the IGBT 41 and the breakdown of the dynamo 22 is prevented. Then, even if Vo increases again, Po is prevented from being output until Vo increases to d. This is provided to prevent a reduction in the maintenance periods of the magnetron 28 or a deterioration in the reliability of the voltage converter 24 by repeatedly intermittently turning on the output signal Po of the magnetron 28 in an operating state of the engine 20 in which Vo assumes a value close to c. Thus, the heater control circuit 56 is provided for controlling the reference voltage generator 54 so that Po behaves in response to the change in Vo as shown in Figure 7.

The heating control circuit 56 is arranged to adjust the heating period tc of the food 30, etc., depending on the change of the output Po of the magnetron as shown in Fig. 8 (a) or 8 (b). Fig. 8 (a) shows a case in which the heating period tc increases in proportion as Po changes through A, B and C, and the operation of the voltage converter 24 is substantially stopped when Po is not more than C. On the other hand, Fig. 8 (b) shows an embodiment in which a range of change of Po is divided into two regions between A and B and between B and C so that different set heating periods tc are assigned to the regions accordingly. Practically, by correcting the heating periods tc in such an arrangement, sufficient heating correction control can be carried out depending on the change of Po. become.

Figure 9 shows a third embodiment including a battery 57, a transmission cable 58, the rectifying device 23, the voltage converter 24, the rectifier 27, the magnetron 28 and the furnace 29. Numerals identical to those mentioned above are used in the same way and the detailed description thereof is abbreviated.

In the embodiment described above, the transmission cable 58 transmits all the electric energy received from the battery to the voltage converter 24 through the rectifier 23. This DC voltage is converted into a high voltage by the voltage converter 24 and rectified by the rectifier 27 to be supplied to the magnetron 28. By the high voltage mentioned above, the magnetron 28 radiates microwaves into the oven 29 to heat the object to be heated 30.

By adopting the above-mentioned arrangement, electric power is stably obtained from the battery 57. Since the transmission cable 58 does not supply electric power other than that for the voltage converter 24, the voltage drop through the transmission cable can be minimized.

Figure 10 shows a fourth embodiment of the present invention. In Figure 10, numeral 135 denotes a heating chamber for accommodating the object to be heated, numeral 136 denotes a first member provided on the bottom surface of the heating chamber and concavely machined in its central part, and numeral 137 denotes a cylindrical second member fitted to the outer edge of the concave part of the first member. These first and second members are fitted together by threaded engagement. Number 138 denotes a magnetron for generating microwaves emitted into the heating chamber, number 139 denotes a waveguide, number 140 denotes a stirrer for swirling the microwaves emitted into the heating chamber, number 141 denotes an intermediate plate, number 142 denotes a door, number 143 denotes a control panel, number 144 denotes a housing, number 145 denotes a power supply for an electronic oven operated by a power source of a motor vehicle, and number 146 denotes a container in which a liquid food is contained.

In the arrangement described above, the container containing the liquid food is placed in the concave part of the first member. By rotating the second member in this state, the depth of the concave part can be varied to a value suitable for the container. Since the container is placed and held in the concave space, spillage of the liquid food can be prevented.

The bottom surface of the heating chamber is temporarily subjected to self-rotation so that the depth of the concave part defined by the first and second members enables the accommodation of not less than half of the container. In order to conveniently rotate the second member, a finger hole for rotation is preferably formed on the upper side of the second member. Furthermore, since each member is made of non-metallic material, the object to be heated is placed above the bottom surface of the heating chamber made of metallic material. Thus, even if the object to be heated has a small thickness, the upper and lower surfaces of the object to be heated can be effectively heated.

Now, an explanation will be given with reference to Fig. 11. In Fig. 11, elements identical to those of Fig. 10 are designated by the same numerals. In Fig. 11, numeral 148 designates a heating chamber for accommodating an object to be heated, and numeral 149 designates a member removably disposed on a side wall of the heating chamber 148. The member 149 is made of a non-metallic material having a low microwave absorption and is formed with a hole 150 of a predetermined shape into which a container placed on the bottom surface of the heating chamber is inserted to be held.

In the arrangement described above, a container 146 in which a liquid food is accommodated is inserted into the predetermined hole of the member 149 to be held by the member 149. Movement of this member 149 is prevented by four sides of the heating chamber enclosing the door 142. Therefore, the container 146 is held in the space of the heating chamber by the member 149. Thus, vibrations of the motor vehicle are transmitted to the container in an additionally dampened manner.

When not in use, the element 149 is stored on the bottom surface of the heating chamber. When the element 149 is stored on the bottom surface of the heating chamber stored or used by taking it out, the hole for inserting the container therein can be used in the entire extent. As described with reference to Figure 10, when the member 149 is stored on the bottom surface of the heating chamber, the heating of the object to be heated can be effectively assisted by the upper and lower surfaces thereof even if the object to be heated has a small thickness.

Also in Figure 12, elements that are identical to those in Figure are designated by identical numbers. In Figure 12, number 151 designates a heating chamber for receiving an object to be heated, number 152 designates an electromagnet which is provided adjacent to a bottom surface of the heating chamber 153 and number 153 designates a container with a bottom surface provided with magnetic material 154.

By the above-mentioned arrangement, when the electromagnet is actuated after the container 153 containing a liquid food is received, the magnetic material provided on the bottom surface of the container is attracted by the magnetic field generated by the electromagnet, so that the container 153 is attracted and held to the bottom surface of the heating chamber.

The actuation of the solenoid is controlled by applying a control associated with the "open" and "closed" states of the door 142, a manual control using an independent actuation button, an automatic control based on the driving state of the motor vehicle, etc., individually or in combination.

INDUSTRIAL APPLICABILITY

As described above, according to the present invention, it is arranged that the output of the dynamo driven by the engine is rectified into a direct current voltage and this direct current voltage is supplied to the magnetron through the voltage converter. If the operating state of the voltage converter is arranged to be controlled by the output generated electric energy detection circuit and the converter control depending on the level of the generated electric output signal, high voltage can be easily supplied to the magnetron even if the engine, the dynamo and the battery, which have a simple structure, are inexpensive. and has poor output stability. Furthermore, even in places where it is difficult to find a commercial power source, the required stable dielectric heating function can be realized, and thus the increasing demand for the use of high frequency heating devices can be satisfied. In particular, in the arrangement in which DC voltage converted from the output of the dynamo is supplied to the magnetron by the voltage converter, since high controllability of the output electric power can be realized, control of the working state corresponding to the output of the dynamo, namely, control of the electric power, can be easily carried out. Since the dynamo and the prime mover are stable, reliable operation and excellent dielectric heating function can be realized at the same time.

In the arrangement in which the direct current voltage is obtained by rectifying the output signal of the dynamo driven by the engine for transporting people or luggage, if the operating state of the voltage converter is designed to be controlled in accordance with the output signal of the dynamo by the output generated electric energy detection means and the converter control means, the dielectric heating device for the transport device can be easily realized by using the dynamo as a voltage generator with a low output stability and a simple structure, and the required dielectric heating function can be stably obtained.

Furthermore, if the converter controller is designed to substantially stop the operation of the converter (a low electric power input operation state in which the output of electromagnetic waves becomes substantially zero is included) when the output of the dynamo does not exceed a predetermined value, the generation of an overload state of the engine and the dynamo by electric power and abnormal operation or confirmation of the converter can be positively prevented and a high frequency heating device with high reliability can be provided.

By using a battery as a DC voltage source, an electric generator such as a dynamo can be eliminated and high frequency heating can be carried out independently even in a location without mobile facilities.

In an arrangement in which the transmission line for the electrical energy to be transmitted from the battery to the converter does not branch, the voltage drop through the transmission line can be minimized and the electrical energy can be stably transmitted to the voltage converter. Furthermore, erroneous operation of other devices due to switching surges of the voltage converter can be prevented.

By adopting an arrangement in which the device body and the operating part are detachably provided from each other, the device body can be mounted even in a compact vehicle. Furthermore, a high-frequency heating device for vehicles can be realized which can be operated from a place where it can be operated most easily during operation and the body can be installed in a place convenient for installation. Thus, the high-frequency heating device can be mounted in a vehicle which is not as large as a recreational vehicle.

In the arrangement in which changes in gravity acting on the device are detected by the acceleration detection device, the centrifugal force detection device or the angular velocity detection device, unstable conditions in the environment of use of the device such as accelerated or decelerated driving state of the mobile device or cornering at a constant speed can be detected and the safe application environment of the device can be clarified for the user.

Claims (4)

1. High frequency heating device which is arranged on a transport device for people, animals, etc., with: a direct voltage source (22, 23; 57; 59; 76; 11 2); a voltage converter (24; 61; 79; 122) which receives direct voltage from the direct voltage source (22, 23; 57; 59; 76; 11 2); a magnetron (28; 62; 80; 104) which is operated by the output signal of the voltage converter (24; 61; 79; 122); a DC voltage output detection device (31) for directly or indirectly detecting the level of the output signal of the DC voltage source; and a controller (32) for controlling the operation of the voltage converter; characterized by an anode current detecting device (50) for detecting an anode current flowing through the magnetron; a reference signal generator (54); and an error amplifier (55) for outputting a difference between an output signal of the anode current detection device (50) and an output signal of the reference signal generator (54); wherein the controller is a pulse width modulation (PWM) control circuit (53) for controlling the operation of the voltage converter on the basis of an output signal of the error amplifier (55) so that the output signal of the reference signal generator (54) is controlled in accordance with the output signal of the DC voltage detection device (31). 2. High frequency heating device according to claim 1, in which the DC voltage source (22, 23) is formed by a dynamo (22) and a rectifier device (23) for rectifying the output signal of the dynamo (22). 3. High frequency heating device according to claim 1, wherein the DC voltage source (57; 11 2) is formed by a battery. 4. High frequency heating device according to claim 1, 2 or 3, in which a feed line from the DC voltage source (22, 23; 57; 59) to the voltage converter (24; 61) has no branch line.